DE19606883C1 - Electromagnetic relay with combined contact- and reset-spring - Google Patents

Abstract

The relay has a magnetic system (4) which includes a coil (41,42), a stationary core and yoke (43) and a pivoted armature (44) and a contact device (2) with an elongate contact spring (22) having a movable contact (29) and at least one contact carrier (25,27) supporting a cooperating stationary contact (26,28). An operating element (3) is coupled to the armature and the contact spring, the latter forming part of a switching spring (21) with a resetting spring section (23b) for the operating element lying in the same plane as the contact spring.

Description

The invention relates to an electromagnetic relay with egg magnet system, which consists of a coil, a fixed core Yoke arrangement and a pivotally mounted anchor comprises also with a contact arrangement that is an elongated Contact spring with a movable contact and at least one NEN contact carrier includes a fixed contact, as well as with egg Nem actuator, which on the one hand with a moveable Chen end section of the anchor and on the other hand with the con clock spring is coupled, the contact spring being part of a Switch spring clamped on one side, which is also a forms return spring coupled to the actuator.

EP 0 375 398 A2 describes an unpoled relay with a flat magnet system and one below the magnet system arranged normally open contact arrangement shown. The Be The contact spring is actuated via a lever-type Actuator, which itself swivels in the housing gert and with both the anchor and the Kontaktfe of the points of contact because of the separate storage of the actuator each with relative movements experienced friction. Added to this is the bearing friction of the Be Acting body itself. The anchor provision takes place there directly through the contact spring. With this arrangement a changeover contact is difficult to implement because An core vibrations in the idle state directly on the NC contact  would impact clock. There is also an additional anchor feed which is required to keep the anchor in place.

From DE 26 27 168 B2 a relay is already a known type with general structure known in which a separate reset leg abge from the contact spring is branched, with corresponding opposite bending different biasing forces are generated. Everything However, due to the switching spring shown there, it is not an exact one Guidance of the actuator possible. For the practical The design of this system is therefore an additional frictional guidance required for the actuator Lich.

A switching relay is known from DE 39 08 442 C2 Switch spring in a switch room below the magnet system is arranged and the contacting end portion in egg nem enlarged contact space in extension of the anchor end lies. To reset the anchor there is next to the Switch spring itself an additional anchor retaining spring. To con tact actuation is an actuator with the anchor fixed connected, resulting in some friction between actuation supply organ and switching spring results.

From DE 36 44 172 C2 is an electromagnetic Switch drive for an electrical switching device known, at which a flat armature is arranged on the coil face and with its movable end a contact carrier parallel to Coil axis moved. To save a separate proof spring for the armature, the coil body forms a stop channel te that acts as a lever joint. When resetting the To kers in its rest position he rolls on this stop edge , whereby its end of the bearing is pressed against the yoke.

The aim of the present invention is to improve the Relay mentioned in the way that with as possible we few and easily manufactured parts a compact relay construction and a low-friction actuation of the contact spring can be enough. A switch spring with back setting function can be realized, which is an exact and clean low-practice guidance of the actuator allows, whereby a low response power is also achieved. At correspond Chender design it should also with this switch spring be able to save your own anchor spring.

According to the invention, this is the goal of a relay gangs mentioned achieved in that the return spring lies at least approximately in one plane with the contact spring and that that perpendicular to the longitudinal extension of the switching spring movable actuator via the return spring  at least two articulation points along one to the pivot axis the switch spring parallel line is guided.

In the invention, therefore, a switching spring is used, which in essentially in a common plane and in one piece both the contact spring and the return spring forms and by a simple cutting process can be made. Here it is of course not excluded that individual feather lobes, whether for resetting or for making contact, for example for Ju station slightly bent out of the common spring plane will. Basically, however, there are none for this switch spring strong bends or bends in different planes required that require a complicated manufacturing process would. The return spring also forms at least two flush operating points through which the Actuator detected and guided with low friction, wherein the pivot points spaced apart from each other are also Si Protection against lateral tipping and against friction on others Form construction parts.

Although also a one-leg return spring at correspond chender width in the area of the actuator the invented the guide can enable, has the reset spring preferably two separate reset pins kel, either on either side of the actual contact spring on the outside or with a frame-shaped design the contact spring inside their side legs can. The actuator will correspond in any case be designed accordingly. This offers a symmetrical Ge Design of the switch spring, also with a view to a symmetri force distribution with as little friction as possible. At the mentioned frame shape of the contact spring are the two  Reset leg preferably by fork-shaped design the return spring formed, these two back adjusting leg next to the side legs of the contact extend spring within their frame shape. The Ankopp tion to the actuator is preferably done by Füh tion noses, each on the two rest legs opposite to each other and transverse to their longitudinal extent are angled and in mutually aligned guide grooves engage the actuator. In the preferred version design is the actuator with its outer contour adapted the fork shape of the return spring and between them Reset legs out.

The contact spring is expediently via at least one Be branched off from it, lying outside the current path actuation flaps each with an associated switch cam of the actuator, the switching cam depending because of the pivot points of the return spring in bet direction is offset. By the latter There is an offset even with a completely flat shift spring different preload for the contact actuation and for resetting the anchor. The one outside the current case the lying operating tab has the advantage that it is high switching capacities is heated less than the egg general current-carrying areas of the contact spring. In order to one also avoids the risk of thermal deformation of the loading actuator. In a preferred embodiment of the contact with the frame shape mentioned above are expedient also two actuating tabs from the contact section the contact spring towards the inside of its frame  branched in such a way that their ends each one Face the end of a reset leg.

In a further embodiment of the relay, the magnet system an essentially flat anchor that approximates extends parallel to the switching spring, at one end via egg NEN end portion is supported on a core portion and with the other, movable end over the actuator gan biased away from the magnet system by the return spring is, the anchor with its central portion on one to Bearing axis parallel lever line of a body swivel bar rests, so that due to the leverage its storage End section is pressed into the bearing. With one The switch spring can thus be configured via the actuation link also press the anchor into its bearing so that it also bears against the core when the magnet system is not excited, so that an additional anchor spring is not required. This Function of the anchor bracket via the switching spring can be used in the Relay according to the invention advantageously also for a changeover contact can be used, since the holding function by the functionally separate return spring and a loading The armature mass does not impair the break contact is to be feared. The mentioned lever line as a pivot point for the anchor is preferably by one on the base body trained rolling edge generated. But that would also be conceivable the reverse case, that a kink formed at anchor or Unroll the roll bar on a flat surface of the body could.

The invention is based on exemplary embodiments hand of the drawing explained in more detail.

It shows

Fig. 1 shows a relay according to the invention designed in exploded representation,

FIG. 2 an assembled relay of FIG. 1 cut in the longitudinal,

Fig. 3 is a switch spring with the spring support and actuator in a perspective view;

Fig. 4 is a perspective view of the magnetic system of Fig. 1,

Fig. 5 is a perspective view from above of the base body of FIG. 1,

Fig. 6 is a detail view of the actuator,

Fig. 7 is a perspective view of the underside of the base body with mounted contact assembly,

Fig. 8 and 9 show two modified embodiments of the switching spring in each case in a manner analogous to Fig. 3 representation.

The relay shown in FIGS. 1 to 7 is shown in FIG. 1 comprises a base body 1, the egg ne on its bottom contact assembly 2 carries with an actuator 3, such as an arranged above the base body magnet system 4. The relay system is arranged in a housing which is formed by a base plate 5 and a cap 6 .

The base body 1 is box-shaped made of insulating material and forms a partition 11 between the magnet system 4 and the contact arrangement 2 , which has only one opening 12 for the actuator 3 . Below the partition 11 , a control room 13 is formed, which is surrounded by side walls 14 of the base body and which merges on one side by a stepped design of the partition 11 into a contact space 13 a with a greater height. In the control room extends over the largest part of its length, a switching spring 21 approximately parallel to the bottom of the relay, which is defined by the base plate 5 . The switching spring 21 is cut as a ne ne leaf spring and forms a frame-shaped con tact spring 22 with current-carrying side legs 22 a, which unite towards the free end to form a contact section 22 b; on this a movable contact 29 is attached. In addition, on the contact portion 22 b two actuating tabs 22 c are cut free on both sides within the frame shape, in such a way that they point in the direction of the clamping point.

In addition, the switching spring 21 integrally with the con tact spring 22 a fork-shaped return spring 23 , which is essentially separated from the attachment end 21 a of the switching spring starting from the contact spring 22 and with two return legs 23 a substantially parallel within the frame shape of the contact spring 22 parallel to the sides of the legs 22 a extends (see also Fig. 3). The return spring 23 forms with its return legs 23 a U-shape, the supply member 3 is adapted to the outer contour of the actuator 3 to be described.

The switching spring 21 is attached to its fastening end 21 a on egg nem spring support 24 , which in turn is provided via fastening tabs 24 a in insertion shafts 14 on opposite side walls 15 of the base body 1 . The attachment lugs 24 a have hook-shaped contours for better anchoring; in addition, on the spring carrier 24 to a flag 24 b is formed, which is guided through a corresponding opening of the base plate 5 to the outside.

The contact arrangement further comprises a normally closed contact carrier 25 with a normally closed contact 26 and a normally open contact carrier 27 with a normally open contact 28 . Both contact carriers are anchored via fastening sections 25 a and 27 a in corresponding plug-in shafts 16 of the base body 1 . In addition, they each have terminal lugs 25 b and 27 b, which are guided through the base plate 5 to the outside. The contact carrier 25 and 27 are designed and arranged in the contact space 13 a so that the movable contact 29 selectively interacts with the normally closed contact 26 and the normally open contact 28 .

The arranged above the base body magnet system 4 be sits a bobbin 41 with a winding 42 , the axis of which is parallel to the bottom of the relay. A core yoke 43 integrally forms a core leg 43 a, which extends axially through the entire coil, and a yoke leg 43 b, which extends parallel to the core leg below the coil close to the winding up to about half the coil length. An anchor 44 extends with its main part flat in extension of the yoke leg 43 b, with a cross-section reset pole end portion 44 a overlaps a likewise reduced cross-section pole portion 43 c of the yoke leg. A bearing end portion 44 b of the armature is angled toward the free core end 43 d and stored in a pocket 45 of a coil former flange 41 a in such a way that it rolls on the free core end 43 d. The bobbin flange 41 a surrounds this free core end 43 d on three sides and secures the bearing end portion 44 b of the armature with retaining ribs 41 b against migration in the axial direction of the coil. Otherwise, this bearing end portion 44 b of the armature is pressed into the bearing on the core end 43 d by the restoring force of the restoring spring 23 . This restoring force acts on the movable armature end 44 c and pulls it away from the coil. As a result, the armature is levered as a lever when the magnet system is not excited about a rolling edge 17 on the top of the partition 11 - counterclockwise in the illustration of FIG. 2 - so that the bearing end portion 44 b of the armature is prestressed into the bearing . In this way, a separate bearing spring is not necessary.

The arrangement of the yoke leg 43 b directly on the winding 42 (optionally with an insulating intermediate layer) pulls the armature 44 toward the coil when the magnet system is excited, so that the switching spring 21 is also pulled in this direction via the actuating member 3 . In this way, the large contact space 13 a already mentioned results below the yoke leg 43 b, while the lower switching space 13 below the moving armature is sufficient for the switching spring 21 . The actuator 3 , which transmits the switching movement of the armature, has a hook part 31 , the breakthrough 12 of the separating wall 11 passes through in wesent union perpendicular to the base plane and is hooked with its hook-shaped end to an opening 44 d of the armature 44 . Over the free end of this hook part 31 , a recess 43 e is also provided in the pole section 43 c of the pole leg 43 b, which enables a full contact of the armature on the yoke leg in this area.

In addition, the actuator has a flat foot portion 32 which lies substantially in the plane of the switching spring 21 and in this example has an M-shaped shape. The middle leg of the M is at the hook part 31 angeun the. In both outer legs of the foot part 32, a guide groove 33 is formed respectively in each of which a Füh approximately nose 23 b of the neighboring return leg 23 a engages a. At the free ends of these outer legs an actuating cam 34 is formed laterally, which lies below the adjacent actuating tab 22 d of the contact spring and brings the contact spring into the closed position with an upward movement of the actuating member 3 . By adjusting the heights of the apex on the actuation cam 34 on the one hand and the guide grooves 33 on the other hand, the return position of the armature can be adjusted with respect to the closed position of the normally closed contact, even if the return spring and the contact spring are originally in one plane. Otherwise, a corresponding de position can also be adjusted by a slight bend in the return leg 23 a on the one hand or the actuating flap 22 c on the other hand.

To increase the insulation between the magnet system and the contact arrangement, an insulating collar 18 is formed on the partition wall 11 towards the bottom, which engages in a labyrinthine manner between the legs of the M-shaped foot part 32 of the actuating member of FIG. 3 and in this way creates long creepage distances.

The assembly of the relay takes place in such a way that on the one hand the magnet system according to FIG. 4 is preassembled and on the other hand the contact arrangement 3 is anchored in the base body from the underside. The magnet system according to FIG. 4 is assembled with the base body according to FIG. 5, with coil connecting pins 46 being inserted into corresponding openings in the base body. Then the actuator 3 is inserted from the bottom through the frame-shaped switching spring and hooked into the armature. For this purpose, the actuator 3 is first in oblique Stel development, as shown in Fig. 2 dashed with the reference numeral 3 ', led upwards, inserted with the hook part 31 in the opening 12 and then pivoted into the final position. This type of assembly of the actuating element without locking connections also avoids any plastic abrasion that could endanger the contacts. By placing the bottom plate 5 and the cap 6 , the Ge housing is formed, which can also be sealed in a known manner.

The function of the relay already results from the described assignment of the individual parts. Upon excitation of the Magnetsy stems the armature with its pole end portion 44 a is attracted to the pole portion 43 c of the yoke leg 43 b, whereby the contact spring 22 e is pulled upward via the actuator 3 and the movable contact 29 with the closer contact 28 is in contact brought. When the excitation is switched off, the return spring 23 pulls the actuating member 3 and the end 44 c of the armature downward with its return legs 23 a, the armature tilting like a lever on the rolling edge 17 and its bearing end section 44 b even without coil excitation to the yoke end 43 d is biased.

In FIGS. 8 and 9 are two further embodiments of the possible speeds of the switching spring shown and according to the operating Glienicke. In this case, according to Figure 8 121 has the switching spring Fig., A contact spring 122 which 3 now only one, possesses a modification relative to the contact spring 22 of FIG. A TIG disposed leg, clock section at the end of a con 122 b the movable contact 29 carries. The return spring 123 is formed in this case by two on both sides next to the outer sides of the contact spring return leg 123 a formed, each having at their free ends angled actuating lugs 123 b. Accordingly, the modified form of the switching spring 123 , a modified actuator 103 is also provided. This sits a U-shaped shape with two hook parts 131 as outer legs and a foot part 132 connecting the two hook parts, which extends below the switching spring transversely to this and both a central cam section 134 for actuating the contact spring 122 and two arranged since Lich Has guide grooves 133 for receiving the mentioned guide lugs 123 b. The two hook parts 131 he extend up to the anchor, the anchor of course being designed accordingly on both sides to allow a hanging of the hook parts 131 , and also the base body in its partition instead of the previously described central opening 12 must now have two outer openings. The spring support 24 is designed as in the previous embodiment.

FIG. 9 shows a further modification compared to FIG. 8. The switching spring 221 has, similarly to the switching spring 121, a central contact spring 222 with a contact section 222 b as well as a restoring spring 223 formed by an external restoring leg 223 a , the restoring legs each having a guide lug 223 b at their end. The actuator 203 is similar to the actuator 103 U-shaped. It has two hook parts 231 and a transversely extending foot portion 232, in which guide grooves 233 b formed for receiving the guide noses 223rd The Actuate supply of the contact spring 222 is now not immediately on the center leg 222 a, but on the side of shaped actuating tabs 222 c, which are approximately aligned with the back legs 223 a and each rest on a actuation cam 234 of the actuator 203 . The function for adapting the armature and the base body to the modified actuator is the same as for FIG. 8. Otherwise, the function results from the description of the first exemplary embodiment.

Claims (15)

1. Electromagnetic relay with a magnet system ( 4 ) which comprises a coil ( 41 , 42 ), a fixed core-yoke arrangement ( 43 ) and a pivotably mounted armature ( 44 ), further with a contact arrangement ( 2 ) an elongated contact spring ( 22 ; 122 ; 222 ) with a movable contact ( 29 ) and at least one contact carrier ( 25 , 27 ) each having a fixed contact ( 26,28 ), and with an actuating member ( 3 ; 103 ; 203 ) , which is coupled on the one hand with a movable end portion ( 44 c) of the armature ( 44 ) and on the other hand with the contact spring ( 22 ; 122 ; 222 ), the contact spring being part of a one-sided clamped switching spring ( 21 ; 121 ; 221 ) which additionally forms a return spring ( 23 ; 123 ; 223 ) coupled to the actuating member ( 3 ; 103 ; 203 ), characterized in that the return spring ( 23 ; 123 ; 223 ) at least approximately in one plane with the contact spring ( 22 ; 122 ; 222 ) lies and that the right to the longitudinal extension of the switching spring ( 21 ; 121 ; 221 ) be movable actuator ( 3 ; 103 ; 203 ) through the Rückstellfe ( 23 ; 123 ; 223 ) over at least two articulation points ( 33 ; 133 , 233 ) along a line parallel to the pivot axis of the switching spring is guided. 2. Relay according to claim 1, characterized in that the con tact spring (22) has a frame shape with two outgoing from a common fixing point of the switch spring current-carrying side legs (22a) which NEM at the free end to egg the movable contact (29) combine transferring contact portion (22 b), and that the return spring (23) has two adjacent the side limbs (22 a) (23 a) forms extending return leg. 3. Relay according to claim 2, characterized in that the two return legs ( 23 a) are formed by fork-shaped design of the return spring ( 23 ) and each extend alongside the side legs ( 22 a) of the contact spring ( 22 ) within de ren frame shape. 4. Relay according to claim 1, characterized in that the switching spring ( 121 ; 221 ) forms an elongated, central contact spring ( 122 ; 222 ), on each side of which a return leg ( 123 a; 223 a) extends. 5. Relay according to one of claims 2 to 4, characterized in that the two resetting legs ( 23 a; 123 a; 223 a) each have opposite to each other and transverse to their longitudinal extension angled guide lugs ( 23 b; 123 b; 223 b), which engage in mutually aligned guide grooves ( 33 ; 133 ; 233 ) of the actuating element of the ( 3 ; 103 ; 203 ). 6. Relay according to claim 3 or 5, characterized in that the actuating member ( 3 ) is adapted with its outer contour to the fork shape of the return spring ( 23 ) and between the return legs ( 23 a) is guided. 7. Relay according to one of claims 1 to 6, characterized in that the con clock spring ( 22 ) via at least one branched from it, lying outside the current path operating tabs ( 22 c; 222 c) each by an associated switching cam ( 34 ; 234 ) of the actuator ( 3 ; 203 ) is actuated. 8. Relay according to claims 3 and 7, characterized in that two actuating tabs ( 22 c; 122 c; 222 c) branch off from the contact section ( 22 b; 122 b; 222 b) of the contact spring ( 22 ; 122 ; 222 ) such that their ends each face one end of a reset leg ( 23 a; 123 a; 223 a). 9. Relay according to one of claims 1 to 8, characterized in that the magnet system has a substantially flat armature ( 44 ) which extends approximately parallel to the switching spring ( 21 ), at one end via a bearing end portion ( 44 b) is mounted on a core section ( 43 d) and is biased with its opposite, movable end section ( 44 c) via the actuating member ( 3 ) by the return spring ( 23 ; 123 ; 223 ) away from the magnet system ( 4 ) , wherein he cut with his Mittelab on a lever line parallel to the bearing axis ( 17 ) of a base body ( 1 ) is pivotable, so that due to the leverage its bearing end portion ( 44 b) is pressed into the bearing. 10. Relay according to claim 9, characterized in that the lever line is defined by a rolling edge ( 17 ) of the base body. 11. Relay according to claim 9, characterized, that the lever line is fixed by a rolling edge of the anchor sets is. 12. Relay according to one of claims 9 to 11, characterized in that the basic body ( 1 ) forms a partition ( 11 ) between the magnet system ( 4 ) and the contact arrangement ( 2 ), which has only one opening ( 12 ) or openings for the actuator ( 3 ; 103 ; 203 ). 13. Relay according to claim 12, characterized in that the separating wall ( 11 ) forms an insulating collar ( 18 ) projecting towards the underside at the edge of the opening ( 12 ). 14. Relay according to claim 11, characterized in that the actuating member has a U-shaped shape, two side hook parts ( 131 ; 231 ) being attached to the armature and a foot part ( 132 ; 232 ) connecting the two hook parts to the switching spring ( 121 ; 221 ) attacks. 15. Relay according to claim 13, characterized in that the actuation supply member ( 3 ) has a hooked part on the armature hook part ( 31 ) and on the switching spring ( 21 ) engaging foot part ( 32 ), which with the insulating collar ( 18 ) like a labyrinth engages.